Introducing Joint Research Project «Quantum Ampere» for the realisation of the new SI ampere

The metrology community lately has adopted the long-term aim of basing the SI unit system on fundamental constants of nature. The base electrical unit, the ampere, will then be re-defined in terms of a fixed value of the elementary charge e . The most direct realization of the new ampere definition requires controlling the number of electrons which flow in a unit time interval, and of counting the errors occurring in this process of clocking single electrons. State of the art nanofabrication technology allows the fabrication of single-electron transport devices - known as single-electron pumps - which generate electric current by moving electrons one at a time. These devices are capable of delivering currents of about 100 pA with an accuracy at the 1 part per million level. Also, ultrasensitive single-electron detectors have been explored that allow electric charge detection on a resolution level below e . The European Joint Research Project presented here, undertaken by a consortium of several research institutes, aims at further developing the best existing concepts of single-electron pumps and to combine them with single-electron detectors for creating highly accurate quantum current sources, to be used as future current standards. Furthermore, necessary current measurement instrumentation will be developed. The paper comprises the project aims and the main results achieved so far.

[1]  O. Seron,et al.  Quantum metrological triangle experiment at LNE: measurements on a three-junction R-pump using a 20 000:1 winding ratio cryogenic current comparator , 2012 .

[2]  G. Hein,et al.  Robust single-parameter quantized charge pumping , 2008, 0803.0869.

[3]  Klaus Pierz,et al.  Counting statistics for electron capture in a dynamic quantum dot. , 2012, Physical review letters.

[4]  Michael Wulf,et al.  Error accounting algorithm for electron counting experiments , 2012, 1209.1020.

[5]  Dietmar Drung,et al.  A compact 14-bit cryogenic current comparator , 2014, 29th Conference on Precision Electromagnetic Measurements (CPEM 2014).

[6]  Alexander B. Zorin,et al.  Characterization and metrological investigation of an R-pump with driving frequencies up to 100 MHz , 2008 .

[7]  G. G. Stokes "J." , 1890, The New Yale Book of Quotations.

[8]  David A. Ritchie,et al.  Gigahertz quantized charge pumping , 2007 .

[9]  J. Pekola,et al.  Nonadiabatic charge pumping in a hybrid single-electron transistor. , 2008, Physical review letters.

[10]  Juha J. Vartiainen,et al.  Correction: Corrigendum: Hybrid single-electron transistor as a source of quantized electric current , 2007, Nature Physics.

[11]  Klaus Pierz,et al.  Quantized current source with mesoscopic feedback , 2011 .

[12]  G. Hein,et al.  Single-parameter nonadiabatic quantized charge pumping , 2007, 0707.0993.

[13]  D. V. Averin,et al.  Experimental investigation of hybrid single-electron turnstiles with high charging energy , 2009 .

[14]  Dietmar Drung,et al.  Ultrastable low-noise current amplifier , 2014, 29th Conference on Precision Electromagnetic Measurements (CPEM 2014).

[15]  Yu. A. Pashkin,et al.  Single-electron current sources: towards a refined definition of ampere , 2012, 1208.4030.

[16]  D. Ritchie,et al.  Towards a quantum representation of the ampere using single electron pumps , 2012, Nature Communications.